CN220578485U - Card feeding device and temporary card manufacturing equipment - Google Patents

Abstract

The application discloses a certification device and face tablet manufacture equipment, this face tablet manufacture equipment includes certification device, printer, goes out certification device and transfer device. The certification feeding device comprises a conveying mechanism and a double-sheet separating mechanism, wherein the conveying mechanism is used for conveying unprinted certificates. The double-sheet separating mechanism is positioned on the movement path of the certificate and comprises a abutting piece and a friction piece, wherein the abutting piece is used for abutting the friction piece with the certificate. The friction member is used for preventing certificates contacted with the friction member from passing through the friction member in the overlapped two certificates when the overlapped two certificates pass through the friction member. When two overlapped certificates pass through the double-sheet separating mechanism, the friction piece is abutted against one of the two overlapped certificates through the abutting piece, and the certificates contacted with the friction piece in the two overlapped certificates are prevented from passing through the friction piece through the friction resistance of the friction piece, so that the separation of the two overlapped certificates is realized, and the problem of double-sheet of the certificates is avoided.

Description

Card feeding device and temporary card manufacturing equipment

Technical Field

The application relates to the technical field of temporary card manufacturing, in particular to a certification device and temporary card manufacturing equipment.

Background

With the increasing number of cars, many car offices or government offices choose to use self-service temporary license plates in the form of certificates for drivers in order to better serve the drivers. However, the existing temporary manufacturing apparatus often has a problem of re-tensioning of the certificate, for example, when a first certificate is conveyed, a second certificate under the first certificate adheres to the lower surface of the first certificate, resulting in a problem of various information mismatching. Because the temporary license plate is printed in each area and can only be suitable for a certain area, and the density and the style of the used paper are different, the parameters of the temporary license plate manufacturing equipment for conveying the certificate (such as the suction force of the sucking disc for sucking the certificate) cannot be suitable for all areas of the country, and the probability of the problem of the re-tensioning is increased due to the unsuitable parameters of the equipment, so the temporary license plate needs to be improved.

Disclosure of Invention

The utility model mainly solves the technical problems that: the problem that certificate re-tensioning easily occurs when the certificate loading device of the existing temporary card manufacturing equipment performs certificate loading work.

In a first aspect, an embodiment provides a temporary card manufacturing apparatus, comprising:

the device comprises a certification device, a certification device and a printing device, wherein the certification device comprises a conveying mechanism and a double-sheet separating mechanism, and the conveying mechanism is used for conveying unprinted certificates; the double-sheet separating mechanism is positioned on the movement path of the certificate and comprises a abutting piece and a friction piece, wherein the abutting piece is used for abutting the friction piece with the certificate; the friction piece is used for preventing certificates which are contacted with the friction piece from passing through the friction piece in the overlapped two certificates when the overlapped two certificates pass through the friction piece;

A printer for printing information on a certificate;

the certificate issuing device is used for outputting a certificate for completing printing;

and the transfer device is used for transferring certificates among the certification device, the printer and the certification device.

In a second aspect, an embodiment provides a certification device for a temporary card manufacturing apparatus, including:

a transport mechanism for transporting unprinted certificates;

the double-sheet separating mechanism is positioned on the movement path of the certificate and comprises a propping piece and a friction piece, wherein the propping piece is used for propping the friction piece against the certificate; the friction piece is used for preventing certificates which are contacted with the friction piece from passing through the friction piece in the overlapped two certificates when the overlapped two certificates pass through the friction piece.

In one embodiment, the friction piece comprises a mounting shaft, a mounting frame and a friction plate, wherein the mounting shaft is perpendicular to the movement path of the certificate, the mounting frame is rotatably connected with the mounting shaft, and the friction plate covers one side of the mounting frame facing the certificate; the mounting frame can rotate around the mounting shaft so as to drive the friction plate to move close to or far away from the certificate.

In an embodiment, the abutting piece comprises an elastic piece and an abutting seat, one end of the elastic piece abuts against the mounting frame, the other end of the elastic piece abuts against the abutting seat, and elastic restoring force of the elastic piece is used for driving the mounting frame to rotate towards a direction close to the certificate.

In one embodiment, the certificate pressing device further comprises a pressing mechanism, wherein the pressing mechanism is located on the movement path of the certificate and is used for pressing and ironing the certificate passing through the pressing mechanism.

In one embodiment, the pressing mechanism comprises a pressing base, a heating piece, a pressing wheel and a pressing driving assembly, wherein the pressing base is provided with a pressing channel, and the heating piece is arranged in the pressing channel and is used for heating a certificate entering the pressing channel; the pressing driving assembly is used for driving the flattening wheel to rotate and flattening the heated certificate.

In one embodiment, the system further comprises a certificate-depositing base, wherein the certificate-depositing base is provided with a certificate-depositing position and a certificate-depositing position, the certificate-depositing position is used for depositing the unprinted certificate, and the certificate-depositing position is positioned on the transfer path of the transfer device; the conveying mechanism is used for conveying the certificate of the certificate storing position to the upper certificate position; the conveying mechanism comprises a certificate feeding driving assembly and a certificate feeding driving wheel, wherein the certificate feeding driving wheel is used for being in contact with the certificate, and the certificate feeding driving assembly is used for driving the certificate feeding driving wheel to rotate so as to drive the certificate to move.

In one embodiment, the upper certificate driving assembly comprises an upper certificate motor, an upper certificate driving belt wheel, an upper certificate driven belt wheel, an upper certificate driving belt and a first upper certificate rotating shaft; the first upper certificate rotating shaft is rotationally connected with the upper certificate base, and the upper certificate driving wheel is connected with the first upper certificate rotating shaft; the output shaft of the upper evidence motor is connected with the upper evidence driving belt wheel, the upper evidence driven belt wheel is connected with the first upper evidence rotating shaft, and the upper evidence driving belt wheel is connected with the upper evidence driven belt wheel.

In one embodiment, the conveying mechanism further comprises a swinging assembly, and the swinging assembly is arranged above the certificate storing position; the swing assembly comprises a swing frame, a paper rubbing wheel, a swing frame driving assembly and a paper rubbing transmission assembly; the swing frame is provided with a first side and a second side which are oppositely arranged, the first side of the swing frame is arranged on the certificate feeding base in a swinging way, and the paper rubbing wheel is rotationally connected with the second side of the swing frame; the swing frame driving assembly is used for driving the swing frame to swing so as to drive the paper rubbing wheel to move close to and far away from the certificate storage position; the paper rubbing transmission assembly is in transmission connection with the upper certificate driving assembly, the upper certificate driving assembly can drive the paper rubbing wheel to rotate through the paper rubbing transmission assembly, and the paper rubbing wheel is used for driving the contacted certificate to move to be contacted with the upper certificate driving wheel when rotating.

In a third aspect, an embodiment provides a branding manufacturing facility comprising a certification device as defined in any one of the preceding claims.

According to the above embodiment, the certification device and the temporary card manufacturing apparatus include the certification device, the printer, the discharge device and the transfer device. The certification feeding device comprises a conveying mechanism and a double-sheet separating mechanism, wherein the conveying mechanism is used for conveying unprinted certificates. The double-sheet separating mechanism is positioned on the movement path of the certificate and comprises a abutting piece and a friction piece, wherein the abutting piece is used for abutting the friction piece with the certificate. The friction member is used for preventing certificates contacted with the friction member from passing through the friction member in the overlapped two certificates when the overlapped two certificates pass through the friction member. The printer is used for printing information on the certificate, and the certification device is used for outputting the certificate which is printed. The transfer device is used for transferring certificates among the certification device, the printer and the certification device. When a user prints a certificate, the unprinted certificate is transported by a transport mechanism. When two overlapped certificates pass through the double-sheet separating mechanism, the friction piece is abutted against one of the two overlapped certificates through the abutting piece, and the certificates contacted with the friction piece in the two overlapped certificates are prevented from passing through the friction piece through the friction resistance of the friction piece, so that the separation of the two overlapped certificates is realized, and the problem of double-sheet of the certificates is avoided.

Drawings

FIG. 1 is a schematic view of a perspective view of a manufacturing apparatus for a temporary card according to one embodiment of the present application;

FIG. 2 is a schematic diagram of a structure of another view of a manufacturing apparatus for a temporary card according to an embodiment of the present application;

FIG. 3 is a schematic view of a view of the certification device according to an embodiment of the present application;

FIG. 4 is a schematic diagram of an embodiment of the present application illustrating another view of the authentication device;

FIG. 5 is a cross-sectional view of an authentication device in one embodiment of the present application;

FIG. 6 is a schematic view of a view angle of a page turning recovery device according to an embodiment of the present disclosure;

FIG. 7 is a schematic view of a page turning recovery apparatus according to an embodiment of the present disclosure;

FIG. 8 is a schematic diagram illustrating a structure of a viewing angle of the certificate issuing device according to an embodiment of the present application;

FIG. 9 is a schematic diagram of a structure of another view of the certificate issuing device according to an embodiment of the present application;

reference numerals:

100. a certification device;

110. a conveying mechanism; 111. a document feeding driving component; 1111. a certification motor; 1112. the driving belt wheel is used for the upper part; 1113. the upper certificate is from the driven belt wheel; 1114. a certificate feeding driving belt; 1115. a first upper evidence rotating shaft; 1116. a second upper evidence rotating shaft; 1117. a pressure wheel for uploading the certificate; 1118. a syndrome-loading linkage gear; 112. a driving wheel for uploading the certificate; 113. a swing assembly; 1131. a swing frame; 1132. a paper rubbing wheel; 1133. a swing frame drive assembly; 11331. steering engine; 11332. swing arms; 1134. a paper rubbing transmission assembly; 11341. a first paper rubbing belt wheel; 11342. a second paper rubbing belt wheel; 11343. a paper rubbing transmission belt; 120. a double-sheet separating mechanism; 121. a tightening member; 1211. an elastic member; 1212. a pressing seat; 122. a friction member; 1221. a mounting shaft; 1222. a mounting frame; 1223. a friction plate; 130. a certificate loading base; 131. the evidence is stored; 132. go up the syndrome location; 133. a side plate for upper evidence; 1331. a limit groove; 134. fixing shaft for upper evidence; 135. a certificate-feeding channel plate; 136. a forensic channel; 140. an information code scanner; 150. a pressing mechanism; 151. pressing a base; 152. flattening wheels; 153. a pressing driving assembly; 1531. pressing the driving gear; 1532. pressing the driven gear; 160. a double-sheet sensor; 170. a limit component; 171. a limit rod; 172. a rear baffle; 173. a height limiting plate; 174. a width limiting plate; 180. a thickness sensor; 190. an upper evidence sensor;

200. A printer;

300. a page turning recovery device;

310. a page turning base; 311. a page turning channel; 312. a recovery box; 313. a first page turning platform; 314. a second page turning platform; 315. a page turning side plate; 316. a page turning fixed shaft; 317. a page turning channel plate; 320. a channel switching mechanism; 321. a guide gate; 322. switching the driving assembly; 3221. an electromagnet; 3222. a first switching arm; 3223. a second switching arm; 323. switching the rotating shaft; 330. a page turning drive assembly; 331. a page turning motor; 332. turning over a page driving belt wheel; 333. turning over the driven belt wheel; 334. turning over the page driving belt; 335. a first page turning shaft; 336. a second page turning shaft; 337. a page turning pressure wheel; 338. turning over a page tension wheel; 339. a page turning driving wheel; 340. a first page turning sensor; 350. a second page turning sensor;

400. a certificate discharging device;

410. a certificate outlet base; 411. an operating position; 4111. operating the bearing platform; 412. storing bits; 4121. a storage channel; 413. a certificate outlet; 414. a certificate outlet side plate; 415. a certificate outlet fixed shaft; 416. a certificate outlet channel plate; 417. a certificate outlet guide plate; 420. a discharge drive device; 421. a discharge drive assembly; 4211. a discharge motor; 4212. a discharge driving belt wheel; 4213. a certificate-discharging driven belt wheel; 4214. a certificate output driving belt; 4215. a first certificate-discharging rotating shaft; 4216. a second certificate output shaft; 4217. a discharge pressure wheel; 4218. a certificate discharge tensioning wheel; 422. a certificate-discharging driving wheel; 430. a first operation sensor; 440. a second operation sensor; 450. a third operation sensor; 460. a first storage sensor; 470. a second storage sensor;

500. A transfer device;

510. a first transfer assembly; 520. a second transfer assembly; 530. a third transfer assembly; 540. an extraction assembly;

600. a base;

700. and an electric control device.

Detailed Description

The utility model will be described in further detail below with reference to the drawings by means of specific embodiments. Wherein like elements in different embodiments are numbered alike in association. In the following embodiments, numerous specific details are set forth in order to provide a better understanding of the present application. However, one skilled in the art will readily recognize that some of the features may be omitted, or replaced by other elements, materials, or methods in different situations. In some instances, some operations associated with the present application have not been shown or described in the specification to avoid obscuring the core portions of the present application, and may not be necessary for a person skilled in the art to describe in detail the relevant operations based on the description herein and the general knowledge of one skilled in the art.

Furthermore, the described features, operations, or characteristics of the description may be combined in any suitable manner in various embodiments. Also, various steps or acts in the method descriptions may be interchanged or modified in a manner apparent to those of ordinary skill in the art. Thus, the various orders in the description and drawings are for clarity of description of only certain embodiments, and are not meant to be required orders unless otherwise indicated.

The numbering of the components itself, e.g. "first", "second", etc., is used herein merely to distinguish between the described objects and does not have any sequential or technical meaning. The terms "coupled" and "connected," as used herein, are intended to encompass both direct and indirect coupling (coupling), unless otherwise indicated.

The present embodiment provides a temporary card manufacturing apparatus.

Referring to fig. 1 to 9, the temporary card manufacturing apparatus includes a certification device 100, a printer 200, a page turning recovery device 300, a certification device 400, and a transfer device 500. The certification device 100 is used to deliver unprinted certificates, and the printer 200 is used to print information on the certificates. The page turning recovery device 300 is used for turning over the certificate and recovering the discarded certificate, and the discharge device 400 can continuously output at least two printed certificates. The relay device 500 is used to transfer certificates between the certification device 100, the printer 200, the page turning recovery device 300, and the certification device 400.

When the printing work of the certificate is performed, the certification device 100 finishes the certification work of the unprinted certificate, the unprinted certificate is transferred to the first side of the printer 200 to be printed through the transfer device 500, and the certificate printed on the first side is transferred to the page turning recovery device 300 to be turned through the transfer device 500, so that the certificate is transferred to the second side of the printer 200 to be printed. When there is a discarded certificate, the discarded certificate is transferred to the page turning recovery apparatus 300 to be recovered by the transfer apparatus 500. When printing of at least two certificates is completed, at least two certificates for which printing is completed are continuously output by the certification device 400. This greatly shortens the interval between the discharge of the first certificate and the second certificate from the outlet 413, thereby contributing to a reduction in the probability of the user missing the second certificate.

In another aspect, the present embodiment further provides an authentication device 100.

Referring to fig. 1-5, the document feeding device 100 includes a document feeding device 100 including a conveying mechanism 110 and a sheet separating mechanism 120.

The transport mechanism 110 is used to transport unprinted certificates. The double-sheet separating mechanism 120 is located on the moving path of the certificate, and the double-sheet separating mechanism 120 includes a holding member 121 and a friction member 122, the holding member 121 being for holding the friction member 122 against the certificate. The friction member 122 is used to prevent a certificate in contact with the friction member 122 from passing through the friction member 122 from among the overlapped two certificates when the overlapped two certificates pass through the friction member 122.

When a user prints a certificate, the unprinted certificate is transported by a transporting device. When two overlapped certificates pass through the double-sheet separating mechanism 120, the friction piece 122 is abutted against one of the two overlapped certificates through the abutting piece 121, and the certificate contacted with the friction piece 122 in the two overlapped certificates is prevented from passing through the friction piece 122 through the friction resistance of the friction piece 122, so that the two overlapped certificates are separated, and the problem of double-sheet of the certificates is avoided.

Referring to fig. 3-5, in one embodiment, the friction member 122 includes a mounting shaft 1221, a mounting frame 1222, and a friction plate 1223, wherein the mounting shaft 1221 is perpendicular to the movement path of the certificate, the mounting frame 1222 is rotatably connected to the mounting shaft 1221, and the friction plate 1223 covers a side of the mounting frame 1222 facing the certificate. The mount 1222 is rotatable about a mounting axis 1221 to move the friction plate 1223 closer to or further from the certificate.

The installation of the friction plate 1223 on the certificate movement path is realized through the installation shaft 1221 and the installation frame 1222, and the installation frame 1222 is driven to rotate around the installation shaft 1221, so that the friction plate 1223 can be driven to move close to or away from the certificate, and the contact or separation of the friction plate 1223 and the certificate is realized.

Specifically, the mounting shaft 1221 may be connected to the upper document base 130, and the mounting frame 1222 and the friction plate 1223 may be provided in plurality such that the friction plate 1223 is provided opposite to the upper document driving wheel 112 in one-to-one correspondence. The friction plate 1223 may be made of bakelite, so as to obtain better elasticity and larger friction force.

Referring to fig. 3 to 5, in one embodiment, the abutting member 121 includes an elastic member 1211 and an abutting seat 1212, one end of the elastic member 1211 abuts against the mounting frame 1222, the other end abuts against the abutting seat 1212, and an elastic restoring force of the elastic member 1211 is used to drive the mounting frame 1222 to rotate in a direction approaching the certificate.

The elastic restoring force of the elastic member 1211 drives the mount 1222 to rotate in a direction approaching the certificate, so that the friction plate 1223 on the mount 1222 contacts the certificate, thereby separating the re-tensioned certificate passing through the friction plate 1223 by the friction plate 1223. Specifically, the elastic member 1211 may be a spring, a shrapnel, or other suitable elastic structure.

Referring to fig. 3-5, in one embodiment, the certification device 100 further includes a pressing mechanism 150, where the pressing mechanism 150 is located on a movement path of the certificate, and is configured to press and irone the certificate passing through the pressing mechanism 150.

The certificate may undergo deformation or warping under the influence of external environment, thereby affecting the reliability of movement of the certificate when the certificate enters the printer 200 or the channel, and further resulting in an increase in failure rate of the temporary manufacturing equipment. Specifically, since the entrance of the printer 200 and the openings of the various channels are highly restricted, the certificate variation and the warping angle exceeding the restricted height cause the jam, the variation and the warping edge must be controlled to plus or minus 8.0MM. Because the pressing mechanism 150 is added in this embodiment, when the certificate passes through the pressing mechanism 150, the certificate is pressed and ironed by the pressing mechanism 150, so that the variation or the warping angle of the certificate is prevented from affecting the reliability of the movement of the certificate in the temporary card manufacturing equipment, thereby being beneficial to reducing the failure rate of the temporary card manufacturing equipment.

Referring to fig. 3-5, in one embodiment, the pressing mechanism 150 includes a pressing base 151, a heating element (not shown), a pressing wheel 152, and a pressing driving assembly 153, where the pressing base 151 has a pressing channel (not shown), and the heating element is disposed in the pressing channel and is used for heating a certificate entering the pressing channel. The pressing driving assembly 153 is used for driving the pressing wheel 152 to rotate so as to press the heated certificate.

And after the certificate enters the pressing channel, heating the certificate in the pressing channel through the heating piece. The flattening wheel 152 is driven to rotate by the ironing driving assembly 153, and the heated certificate is flattened by the flattening wheel 152. Specifically, the heating element may be a PTC heating plate.

Referring to fig. 3-5, in one embodiment, the press drive assembly 153 includes a press drive motor (not shown), a press drive gear 1531, and a press driven gear 1532. The pressing base 151 is rotatably provided with two pressing shafts, the pressing shafts are provided with pressing wheels 152, and the pressing wheels 152 on the pressing shafts are arranged oppositely. The ironing driving gear 1531 and the ironing driven gear 1532 are connected with the two ironing rotating shafts in one-to-one correspondence, and the ironing driving gear 1531 is meshed with the ironing driven gear 1532.

When the flattening wheel 152 needs to be driven to rotate, the ironing driving gear 1531 is driven to rotate by the ironing driving motor, the ironing driving gear 1531 drives the ironing driven gear 1532 to rotate, and then drives the two flattening rotating shafts and the flattening wheel 152 on the flattening rotating shaft to rotate.

Referring to fig. 3-5, in one embodiment, the certification device 100 further includes a certification base 130, where the certification base 130 has a certification authority 131 and a certification authority 132, the certification authority 131 is used for storing unprinted certificates, and the certification authority 132 is located on a transfer path of the transfer device 500. The transport mechanism 110 is configured to transport the certificate of the certificate authority 131 to the certificate authority 132. The conveying mechanism 110 comprises a certificate driving assembly 111 and a certificate driving wheel 112, wherein the certificate driving wheel 112 is used for contacting with a certificate, and the certificate driving assembly 111 is used for driving the certificate driving wheel 112 to rotate so as to drive the certificate to move.

When the certificate is required to be conveyed, the certificate driving wheel 112 is driven to rotate through the certificate driving assembly 111, so that the certificate contacted with the certificate driving wheel 112 is driven to move. In particular, the certification driving wheel 112 may arrange a plurality along the movement path of the certificate so as to drive the certificate to move continuously.

Referring to fig. 3-5, in one embodiment, the document base 130 includes two opposite document side plates 133 and a document fixing shaft 134, and the document fixing shaft 134 fixedly connects the two document side plates 133. The certificate storing position 131, the pressing mechanism 150 and the upper certificate position 132 are sequentially arranged between the two upper certificate side plates 133, so that the support of the certificate storing position 131, the pressing mechanism 150 and the upper certificate position 132 is realized.

Referring to fig. 3-5, in one embodiment, the upper document base 130 further includes two opposite upper document channel plates 135, where the two upper document channel plates 135 are located between the two upper document side plates 133 and enclose the two upper document side plates 133 to form an upper document channel 136, and the upper document channel 136 guides the certificate to move on the upper document base 130.

Referring to fig. 3-5, in one embodiment, the certification device 100 further includes a certification sensor 190, where the certification sensor 190 is disposed on the certification site 132, and the certification site 132 detects whether a certificate exists through the certification sensor 190.

Referring to fig. 3-5, in one embodiment, the device 100 further includes a double-sheet sensor 160, where the double-sheet sensor 160 is disposed adjacent to the upper certificate 132, and the double-sheet sensor 160 is configured to detect whether the certificate is double-sheet. Specifically, the double-sheet sensor 160 may be an infrared detection sensor.

Referring to fig. 3-5, in one embodiment, the forensic drive assembly 111 includes a forensic motor 1111, a forensic driving pulley 1112, a forensic driven pulley 1113, a forensic belt 1114, and a first forensic spindle 1115. The first upper certificate rotating shaft 1115 is rotatably connected with the upper certificate base 130, and the upper certificate driving wheel 112 is connected with the first upper certificate rotating shaft 1115. An output shaft of the upper certificate motor 1111 is connected with an upper certificate driving pulley 1112, an upper certificate driven pulley 1113 is connected with a first upper certificate rotating shaft 1115, and an upper certificate driving belt 1114 connects the upper certificate driving pulley 1112 and the upper certificate driven pulley 1113.

When the upper license driving wheel 112 needs to be driven to rotate, the upper license driving pulley 1112 is driven to rotate by the upper license motor 1111, and the upper license driving pulley 1112 drives the upper license driven pulley 1113 to rotate by the upper license driving belt 1114, so as to drive the first upper license rotating shaft 1115 and the upper license driving wheel 112 to rotate. Specifically, the first upper license rotating shaft 1115 and the upper license driven pulley 1113 may be provided in plurality, so that the upper license driving pulley 1112 may drive the plurality of first upper license rotating shafts 1115 and the upper license driven pulley 1113 to rotate through the upper license driving belt 1114.

Referring to fig. 3-5, in one embodiment, the document drive assembly 111 further includes a second document spindle 1116 and a document pressure wheel 1117, the second document spindle 1116 being rotatably coupled to the document base 130. The upper certificate pressure wheel 1117 is connected to the second upper certificate rotating shaft 1116, and the upper certificate pressure wheels 1117 are disposed opposite to the upper certificate driving wheels 112 in one-to-one correspondence. The certificate is pressed against the certificate-issuing driving wheel 422 by the certificate-issuing pressing wheel 1117, so that the certificate-issuing driving wheel 112 can bring the certificate into motion more stably. Specifically, a spring may be further disposed on the document base 130, and the document pressing wheel 1117 is abutted against the document driving wheel 112 by the elastic force of the spring.

Referring to fig. 3-5, in one embodiment, the forensic driving assembly 111 further includes a forensic linkage gear 1118, the first forensic rotating shaft 1115 and the second forensic rotating shaft 1116 are respectively provided with a forensic linkage gear 1118, and the forensic linkage gear 1118 on the first forensic rotating shaft 1115 is meshed with the forensic linkage gear 1118 on the second forensic rotating shaft 1116, so that the second forensic rotating shaft 1116 can be driven to rotate by the forensic linkage gear 1118 when the first forensic rotating shaft 1115 rotates.

Referring to fig. 3-5, in one embodiment, the conveying mechanism 110 further includes a swing assembly 113, and the swing assembly 113 is disposed above the certificate storing position 131. The swing assembly 113 includes a swing frame 1131, a rubbing wheel 1132, a swing frame drive assembly 1133, and a rubbing drive assembly 1134. The swing frame 1131 has a first side and a second side that are opposite to each other, the first side of the swing frame 1131 is swingably disposed on the upper document base 130, and the paper rubbing wheel 1132 is rotatably connected to the second side of the swing frame 1131. The swing frame driving component 1133 is used for driving the swing frame 1131 to swing so as to drive the rubbing wheel 1132 to move close to and away from the certificate storing position 131. The paper rubbing transmission assembly 1134 is in transmission connection with the upper certificate driving assembly 111, and the upper certificate driving assembly 111 can drive the paper rubbing wheel 1132 to rotate through the paper rubbing transmission assembly 1134, and the paper rubbing wheel 1132 is used for driving the contacted certificate to move to be contacted with the upper certificate driving wheel 112 when rotating.

When the certificate of the certificate storage position 131 is required to be driven to contact with the certificate feeding driving wheel 112, the swing frame 1131 is driven to swing towards the direction close to the certificate storage position 131 by the swing frame driving component 1133, so that the paper rubbing wheel 1132 is driven to contact with the certificate on the certificate storage position 131. The rubbing wheel 1132 is driven to rotate by the rubbing transmission assembly 1134, so that the certificate contacted with the rubbing wheel 1132 is driven to move. Thereby driving the certificate of the certificate holding position 131 into contact with the upper certificate driving wheel 112.

Specifically, the rubbing wheel 1132 may be a unidirectional rubbing wheel 1132, so that the rubbing wheel 1132 can only rotate in one direction, and the rubbing wheel 1132 only provides the certificate with the driving force in the proving direction. The paper rubbing transmission assembly 1134 may be a belt transmission structure or a chain transmission structure. For example, when the paper rubbing transmission assembly 1134 is a belt transmission structure, the paper rubbing transmission assembly 1134 includes a first paper rubbing pulley 11341, a second paper rubbing pulley 11342, and a paper rubbing transmission belt 11343, the paper rubbing pulley 1132 is rotatably connected to the swinging frame 1131 through a paper rubbing rotation shaft, the first paper rubbing pulley 11341 is connected to the first upper card rotation shaft 1115, the second paper rubbing pulley 11342 is connected to the paper rubbing rotation shaft, and the paper rubbing transmission belt 11343 connects the first paper rubbing pulley 11341 to the second paper rubbing pulley 11342. When the upper certificate motor 1111 drives the first upper certificate rotating shaft 1115 to rotate, the first paper rubbing pulley 11341 is driven to rotate, and the first paper rubbing pulley 11341 drives the second paper rubbing pulley 11342 and the paper rubbing rotating shaft to rotate through the paper rubbing driving belt 11343, so as to drive the paper rubbing wheel 1132 to rotate.

Referring to fig. 3-5, in one embodiment, the swing frame driving assembly 1133 includes a steering engine 11331 and a swing arm 11332, the steering engine 11331 is connected to the swing frame 1131, the swing arm 11332 is connected to an output end of the steering engine 11331, and the steering engine 11331 can drive the swing arm 11332 to swing, so that the swing arm 11332 collides with or releases the certificate on the certificate storage location 131.

When the swing arm 11332 collides with the certificate on the certificate storage position 131, the free end of the swing frame 1131 is supported by the swing arm 11332, so that the paper rubbing wheel 1132 is suspended, and the rotation of the paper rubbing wheel 1132 can not drive the certificate to move. When the swing arm 11332 swings to a position where it does not collide with the certificate, the paper rubbing wheel 1132 falls into contact with the certificate on the certificate storage position 131, so that the rotation of the paper rubbing wheel 1132 can drive the certificate to move.

It should be noted that, after the paper rubbing wheel 1132 has performed the certification of a certificate, the swing arm 11332 is driven to swing by the steering engine 11331, so that the swing arm 11332 drives the swing frame 1131 to move in a direction away from the certificate, and further the paper rubbing wheel 1132 is separated from the certificate, so as to avoid the problem of re-tensioning caused by that the paper rubbing wheel 1132 continuously conveys more certificates.

Referring to fig. 3-5, in one embodiment, the document feeding device 100 further includes a limiting assembly 170, wherein the limiting assembly 170 includes a limiting rod 171, a rear baffle 172, a height limiting plate 173, and a width limiting plate 174. The limiting rod 171 is connected to the swing frame 1131, and an arc-shaped limiting groove 1331 is formed in the upper certificate side plate 133, and the end portion of the limiting rod 171 extends into the limiting groove 1331, so that the swing angle of the swing frame 1131 is limited through the interference between the limiting rod 171 and the limiting groove 1331.

The back plate 172 is connected to a side of the certificate storing position 131 away from the pressing mechanism 150, for preventing the certificate from exiting the certificate storing position 131 from the side of the back plate 172 when the driving wheel rotates reversely. The height limiting plate 173 is connected to the upper certificate side plate 133, and the height limiting plate 173 is used for limiting the stacking thickness of the certificates, and can also play a role in compressing the certificates and preventing the warping angle of the certificates. The width limiting plate 174 is connected to the upper certificate side plate 133, and is used for limiting the width of the certificate, and the certificate storing position 131 can be suitable for storing certificates with different width specifications by adjusting the position or thickness of the width limiting plate 174.

Referring to fig. 3-5, in one embodiment, the certification device 100 further includes a thickness sensor 180, where the thickness sensor 180 is connected to the certification side plate 133 for detecting the thickness of the certification on the certification authority 131. When the thickness of the certificate on the certificate deposit 131 exceeds a preset thickness, the thickness sensor 180 can send thickness information to the control system of the temporary card manufacturing apparatus so that the control system sends an error report instruction.

On the other hand, referring to fig. 1-5, the present embodiment further provides a temporary card manufacturing apparatus, which includes the above-mentioned certification device 100.

On the other hand, the embodiment also provides a temporary card manufacturing device.

Referring to fig. 1 to 5, the temporary card manufacturing apparatus includes a card-feeding device 100, a printer 200, a card-discharging device 400, and a transfer device 500.

The certification device 100 includes a conveying mechanism 110 and a double-sheet separating mechanism 120, the conveying mechanism 110 being configured to convey unprinted certificates. The double-sheet separating mechanism 120 is located on the moving path of the certificate, and the double-sheet separating mechanism 120 includes a holding member 121 and a friction member 122, the holding member 121 being for holding the friction member 122 against the certificate. The friction member 122 is used to prevent a certificate in contact with the friction member 122 from passing through the friction member 122 from among the overlapped two certificates when the overlapped two certificates pass through the friction member 122. The printer 200 is used to print information on a certificate, and the certification device 400 is used to output a certificate that completes printing. The relay device 500 is used to transfer certificates between the certification device 100, the printer 200, and the certification device 100.

When the user prints a certificate, the unprinted certificate is transported through the transport mechanism 110. When two overlapped certificates pass through the double-sheet separating mechanism 120, the friction piece 122 is abutted against one of the two overlapped certificates through the abutting piece 121, and the certificate contacted with the friction piece 122 in the two overlapped certificates is prevented from passing through the friction piece 122 through the friction resistance of the friction piece 122, so that the two overlapped certificates are separated, and the problem of double-sheet of the certificates is avoided.

On the other hand, the present embodiment also provides a verification apparatus 400.

Referring to fig. 1, 2, 8 and 9, the document ejection device 400 includes a document ejection base 410 and a document ejection driving device 420.

The certificate exit base 410 includes an operation bit 411, a storage bit 412, and a certificate exit 413, the operation bit 411 being used to carry certificates to be entered and discharged into and from the printer 200, the storage bit 412 being used to store at least one certificate for completing printing. The forensic driving means 420 can drive at least two certificates in the operation bit 411 and/or the storage bit 412 to be continuously discharged from the forensic outlet 413. The relay device 500 is used to transfer certificates between the certification device 100, the printer 200, and the certification device 400.

When the user prints the certificate, the certification device 100 completes the certification work of the unprinted certificate first, and then the transfer device 500 transfers the unprinted certificate to the operation bit 411, and causes the unprinted certificate to enter the printer 200 from the operation bit 411 to be printed. After the first certificate is printed, the first certificate is transferred from the operation position 411 to the storage position 412 for storage, and after the second certificate is printed, the certificate-issuing driving device 420 drives at least two certificates on the operation position 411 and/or the storage position 412 to be continuously discharged from the certificate-issuing port 413. This greatly shortens the interval between the discharge of the first certificate and the second certificate from the outlet 413, thereby contributing to a reduction in the probability of the user missing the second certificate.

Referring to fig. 8 and 9, in one embodiment, the operation bit 411 is configured to operate the carrying platform 4111, and the storage bit 412 is configured to store the channel 4121, where one side of the storage channel 4121 is in communication with the carrying platform, and the other side is in communication with the outlet 413.

The operation position 411 is configured as a carrying platform, so that the transferring device 500 can conveniently operate the certificate from the upper side of the carrying platform. When the printer 200 completes printing a certificate, the printer 200 returns the certificate to the operation position 411, and then moves the certificate to the entrance where the storage channel 4121 communicates with the bearing platform through the transfer device 500.

Referring to fig. 8 and 9, in one embodiment, the document ejection driving device 420 includes a document ejection driving assembly 421 and a document ejection driving wheel 422, where the document ejection driving wheel 422 is used to contact with a document, and the document ejection driving assembly 421 is used to drive the document ejection driving wheel 422 to rotate so as to drive the document to move.

When the certificate needs to be discharged, the certificate discharging driving wheel 422 is driven to rotate by the certificate discharging driving assembly 421, so that the certificate contacting with the certificate discharging driving wheel 422 is driven to move, the certificate in the storage position 412 is driven to be discharged from the certificate discharging port 413, and the certificate at the inlet of the storage channel 4121 is driven to enter the storage channel 4121.

Referring to fig. 8 and 9, in one embodiment, the document ejection drive assembly 421 includes a document ejection motor 4211, a document ejection driving pulley 4212, a document ejection driven pulley 4213, a document ejection belt 4214, and a first document ejection shaft 4215. The first document output shaft 4215 is rotatably connected to the document output base 410, and the document output driving wheel 422 is connected to the first document output shaft 4215. An output shaft of the discharge motor 4211 is connected to the discharge driving pulley 4212, the discharge driven pulley 4213 is connected to the first discharge rotation shaft 4215, and the discharge driving belt 4214 connects the discharge driving pulley 4212 and the discharge driven pulley 4213.

When the certificate needs to be discharged, the discharge driving pulley 4212 is driven to rotate by the discharge motor 4211, and the discharge driving pulley 4212 drives the first discharge rotating shaft 4215 to rotate by the discharge driving belt 4214, so as to drive the first discharge rotating shaft 4215 and the discharge driving wheel 422 to rotate. The certificate in the storage bit 412 is driven out of the certificate outlet 413 by the certificate outlet driving wheel 422, and the certificate at the inlet of the storage channel 4121 is driven into the storage channel 4121.

Referring to fig. 8 and 9, in an embodiment, the document output driving assembly 421 further includes a second document output shaft 4216 and a document output pressure wheel 4217, where the second document output shaft 4216 is rotatably connected to the document output base 410 and is disposed opposite to the first document output shaft 4215 in a one-to-one correspondence. The discharge pressure wheel 4217 is connected to the second discharge shaft 4216, and the discharge pressure wheel 4217 is disposed opposite to the discharge drive wheel 422 in one-to-one correspondence. The discharge driving assembly 421 further includes a discharge tensioning wheel 4218, where the discharge tensioning wheel 4218 is rotatably disposed on the discharge base 410 and is in contact with the discharge driving belt 4214 to tension the discharge driving belt 4214.

The certificate is pressed against the certificate driving wheel 422 by the certificate pressing wheel 4217, so that the certificate driving wheel 422 can more stably bring the certificate into motion. The discharge belt 4214 is tensioned by the discharge tensioner 4218, so that the discharge belt 4214 can more stably drive the discharge driven pulley 4213 to rotate. Specifically, a spring may be further provided on the document base 410, by which the document pressing wheel 4217 is abutted against the document driving wheel 422.

Referring to fig. 8 and 9, in one embodiment, the document base 410 includes two oppositely disposed document side plates 414 and a document securing shaft 415, the document securing shaft 415 connecting the two document side plates 414. The document issuing base 410 further includes two opposite document issuing channel plates 416, where the two document issuing channel plates 416 are located between the two document issuing side plates 414 and enclose with the two document issuing side plates 414 to form a storage channel 4121, and the certificate is guided to move on the document issuing base 410 through the storage channel 4121.

Referring to fig. 8 and 9, in one embodiment, the certificate issuing base 410 further includes a certificate issuing guide plate 417, where the certificate issuing guide plate 417 is disposed on a side of the operation position 411 near the printer 200, and the certificate issuing guide plate 417 is used to guide the certificate on the operation position 411 to move toward the printer 200, so that the certificate on the operation position 411 can enter the printer 200 more smoothly.

Referring to fig. 8 and 9, in one embodiment, the certificate outlet 413 and the operation bit 411 are respectively located at two opposite sides of the storage bit 412, and the operation bit 411 is used to be disposed adjacent to the printer 200.

On the one hand, since the operation position 411 is disposed adjacent to the printer 200, the transfer device 500 is facilitated to convey the certificate on the operation position 411 to the entrance of the printer 200, and the printer 200 is facilitated to return the certificate that has completed printing to the operation position 411. On the other hand, since the discharge port 413, the storage bit 412, and the operation bit 411 are sequentially arranged along a straight line, it is convenient for the discharge driving assembly 421 to continuously discharge at least two certificates on the storage bit 412 and the operation bit 411.

Referring to fig. 8 and 9, in one embodiment, a first operation sensor 430 and a second operation sensor 440 are disposed on a side of the operation bit 411 away from the storage bit 412, where the first operation sensor 430 is used to detect whether a certificate on the operation bit 411 enters the printer 200, and the second operation sensor 440 is used to detect whether a certificate that completes printing is rolled back to the operation bit 411. A third operation sensor 450 is arranged on one side of the operation bit 411 near the storage bit 412, and the third operation sensor 450 is used for detecting whether the certificate is located at a positioning position on the operation bit 411.

Whether the certificate on the operation position 411 enters the printer 200 is detected by the first operation sensor 430, and whether the certificate on the operation position 411 enters the printer 200 is detected by the second operation sensor 440, so that a hardware basis is provided for realizing the automatic control of the temporary manufacturing equipment. Whether the certificate is located at a positioning position on the operation position 411 is detected by the third operation sensor 450, and in particular, the positioning position may refer to a position where the certificate is aligned with the page turning passage 311 of the page turning recovery apparatus 300.

Referring to fig. 8 and 9, in one embodiment, a first storage sensor 460 is disposed on a side of the storage bit 412 near the operation bit 411, where the first storage sensor 460 is used to detect whether a certificate enters the storage bit 412. The side of the storage bit 412 near the outlet 413 is provided with a second storage sensor 470, and the second storage sensor 470 is used for detecting whether the certificate in the storage bit 412 is taken out from the outlet 413.

Whether the certificate enters the storage bit 412 is detected by the first storage sensor 460, whether the certificate in the storage bit 412 is fetched from the certificate exit 413 is detected by the second storage sensor 470, and a hardware basis is provided for automated operation of the certificate entering the storage bit 412 and reminding when the certificate is fetched.

On the other hand, referring to fig. 1, 2, 8 and 9, the present embodiment further provides a temporary card manufacturing apparatus, which includes the above-mentioned evidence device 400.

On the other hand, referring to fig. 1, 2, 8 and 9, the present embodiment further provides a temporary card manufacturing apparatus, which includes a certification device 100, a printer 200, a certification device 400 and a transfer device 500. The certification device 100 is used to deliver unprinted certificates, and the printer 200 is used to print information on the certificates. The discharge apparatus 400 includes a discharge base 410 and a discharge drive assembly 421, the discharge base 410 including an operation bit 411, a storage bit 412, and a discharge port 413, the operation bit 411 being used to carry a certificate to be entered and discharged into and from the printer 200, the storage bit 412 being used to store at least one certificate for which printing is completed. The forensic driving component 421 can drive at least two certificates on the operation bit 411 and/or the storage bit 412 to be continuously discharged from the forensic outlet 413. The relay device 500 is used to transfer certificates between the certification device 100, the printer 200, and the certification device 400.

When the user prints the certificate, the certification device 100 completes the certification work of the unprinted certificate first, and then the transfer device 500 transfers the unprinted certificate to the operation bit 411, and causes the unprinted certificate to enter the printer 200 from the operation bit 411 to be printed. The first certificate is transferred from the operation position 411 to the storage position 412 for storage after printing, and after the second certificate is also printed, the certificate-issuing driving component 421 drives at least two certificates on the operation position 411 and/or the storage position 412 to be continuously discharged from the certificate-issuing port 413. This greatly shortens the interval between the discharge of the first certificate and the second certificate from the outlet 413, thereby contributing to a reduction in the probability of the user missing the second certificate.

Referring to fig. 1 and 2, in one embodiment, the temporary card manufacturing apparatus further includes a base 600, the base 600 has a first side and a second side that are opposite to each other, the document feeding device 100 and the document discharging device 400 are disposed on the first side of the base 600 side by side, the printer 200 is disposed on the second side of the base 600, and the page turning recovery device 300 is disposed between the first side and the second side of the base 600. The relay device 500 is disposed above the document feeding device 100, the document discharging device 400, the page turning recovery device 300, and the printer 200.

On the one hand, the layout method reasonably utilizes the bearing space on the base 600, so that the layout of each functional module in the temporary card manufacturing equipment is compact, and the size of the temporary card manufacturing equipment is reduced. On the other hand, the transfer apparatus 500 is enabled to conveniently realize the scheduling of certificates above the certification apparatus 100, the discharge apparatus 400, the page turning recovery apparatus 300, and the printer 200.

Referring to fig. 6 and 7, in one embodiment, the page turning recovery apparatus 300 includes a page turning base 310, a channel switching mechanism 320, and a page turning driving assembly 330, wherein the page turning base 310 has a page turning channel 311 and a recovery box 312. The page turning driving component 330 is configured to drive the certificate to move along the page turning channel 311, so as to implement page turning of the certificate. The channel switching mechanism 320 is used to selectively communicate or close the page turning channel 311 with the recovery box 312, so that the certificate can drop from the page turning channel 311 into the recovery box 312 when the page turning channel 311 communicates with the recovery box 312.

When the printer 200 has completed printing the first side of the certificate, the certificate needs to be flipped over in order to print the second side of the certificate. At this time, the certificate needs to be moved to the entrance of the page turning channel 311 by the transferring device 500, and then the page turning driving assembly 330 drives the certificate to move along the page turning channel 311, so that the page turning of the certificate can be realized after the certificate is discharged from the exit of the page turning channel 311.

And when there is a certificate that needs to be discarded, for example, when the information code scanner 140 scans that the information codes of the first certificate and the second certificate do not match, the first certificate needs to be discarded. At this time, the certificate may be moved to the entrance of the page turning channel 311 by the transferring device 500, and then the certificate is driven to move along the page turning channel 311 by the page turning driving assembly 330. When the certificate moves to the channel switching mechanism 320, the page turning channel 311 is communicated with the recycling bin 312 through the channel switching mechanism 320, so that the discarded certificate falls into the recycling bin 312 from the page turning channel 311, and recycling is completed.

Referring to fig. 6 and 7, in one embodiment, the channel switching mechanism 320 includes a guide gate 321 and a switching driving component 322, the guide gate 321 is rotatably connected to the page turning base 310, the switching driving component 322 is connected to the guide gate 321, and the switching driving component 322 can drive the guide gate 321 to rotate so as to realize opening or closing of the guide gate 321, and when the guide gate 321 is opened, the certificate in the page turning channel 311 is guided to move continuously in the page turning channel 311, and when the guide gate 321 is closed, the certificate in the page turning channel 311 is guided to move into the recovery box 312.

When the certificate needs to be turned, the switching driving component 322 drives the guide gate 321 to open, so that the certificate can move along the page turning channel 311 to realize page turning. When the certificate needs to be discarded, the switch driving component 322 drives the guide gate 321 to be closed, so that when the certificate moves to the guide gate 321, the certificate moves into the recycling bin 312 under the guidance of the guide gate 321, and recycling is completed.

Referring to fig. 6 and 7, in one embodiment, the switching driving assembly 322 includes an electromagnet 3221, a first switching arm 3222 and a second switching arm 3223, the electromagnet 3221 is connected to the page turning base 310, the first switching arm 3222 and the second switching arm 3223 each have a first end and a second end, the first end of the first switching arm 3222 is connected to the movable end of the electromagnet 3221, and the second end of the first switching arm 3222 is rotatably connected to the first end of the second switching arm 3223. The guide gate 321 is rotatably connected to the page turning base 310 through a switching shaft 323, and a second end of the second switching arm 3223 is connected to the switching shaft 323. The movable end of the electromagnet 3221 can drive the first end of the first switching arm 3222 to move, so as to drive the switching shaft 323 to rotate.

When the guide gate 321 needs to be driven to rotate, the electromagnet 3221 is electrified or powered off, the movable end of the electromagnet 3221 is driven to move, the movable end of the electromagnet 3221 is used for driving the first switching arm 3222 and the second switching arm 3223 to move, and then the switching rotating shaft 323 and the guide gate 321 are driven to rotate, so that the guide gate 321 is driven to be opened or closed. Of course, in other embodiments, the switching driving assembly 322 may also be a cylinder, a motor or other suitable power source, and a rack-and-pinion structure, a driving transmission structure or other suitable transmission structure.

Referring to fig. 6 and 7, in one embodiment, the page turning driving assembly 330 includes a page turning motor 331, a page turning driving pulley 332, a page turning driven pulley 333, a page turning belt 334, a first page turning shaft 335, and a page turning driving wheel 339. The first page turning shaft 335 is rotatably connected to the page turning base 310, and the page turning driving wheel 339 is connected to the first page turning shaft 335. An output shaft of the page turning motor 331 is connected with a page turning driving pulley 332, a page turning driven pulley 333 is connected with a first page turning rotating shaft 335, and a page turning driving belt 334 connects the page turning driving pulley 332 and the page turning driven pulley 333.

When the certificate is required to be driven to move in the page turning channel 311, the page turning motor 331 drives the page turning driving pulley 332 to rotate, the page turning driving pulley 332 drives the first page turning rotating shaft 335 to rotate through the page turning driving belt 334, and further drives the page turning driven pulley 333 and the page turning driving wheel 339 to rotate, and the page turning driving wheel 339 drives the certificate in the page turning channel 311 to move.

Referring to fig. 6 and 7, in one embodiment, the page turning driving assembly 330 further includes a second page turning shaft 336 and a page turning pressure wheel 337, where the second page turning shaft 336 is rotatably connected to the page turning base 310 and is disposed opposite to the first page turning shaft 335 in a one-to-one correspondence manner. The page turning pressure wheel 337 is connected to the second page turning shaft 336, and the page turning pressure wheel 337 is disposed opposite the page turning drive wheels 339 in a one-to-one correspondence. The page turning driving assembly 330 further includes a page turning tensioning wheel 338, where the page turning tensioning wheel 338 is rotatably disposed on the page turning base 310 and abuts against the page turning driving belt 334 to tension the page turning driving belt 334.

Pressing the certificate against the page turning drive wheel 339 by the page turning press wheel 337 enables the page turning drive wheel 339 to more stably carry the certificate in motion. The page turning belt 334 is tensioned by the page turning tensioning wheel 338, so that the page turning belt 334 can more stably drive the page turning driven pulley 333 to rotate. Specifically, a spring may be further provided on the page turning base 310, and the page turning pressure wheel 337 is abutted against the page turning driving wheel 339 by the spring.

Referring to fig. 6 and 7, in one embodiment, a first page turning platform 313 is disposed at an inlet of the page turning channel 311, the page turning platform is used for supporting the certificate before entering the page turning channel 311, a first page turning sensor 340 is disposed on the page turning platform, and the first page turning sensor 340 is used for detecting whether the certificate exists on the page turning platform. The outlet of the page turning channel 311 is provided with a second page turning platform 314, the second page turning platform 314 is used for bearing the certificate of the discharged page turning channel 311, the second page turning platform 314 is provided with a second page turning sensor 350, and the second page turning sensor 350 is used for detecting the position of the certificate on the second page turning platform 314.

Referring to fig. 6 and 7, in one embodiment, the page turning base 310 includes two oppositely disposed page turning side plates 315 and a page turning fixing shaft 316, and the page turning fixing shaft 316 connects the two page turning side plates 315. The page turning base 310 further includes two oppositely disposed page turning channel plates 317, where the two page turning channel plates 317 are disposed between the two page turning side plates 315 and enclose the two page turning side plates 315 to form a page turning channel 311, at least part of the page turning channel 311 is in an arc structure, and the page turning channel 311 guides the movement of the certificate to realize 180 ° page turning of the certificate.

Referring to fig. 6 and 7, in one embodiment, the temporary manufacturing apparatus further includes an information code scanner 140, the information code scanner 140 is located on a movement path of the certificate, and the information code scanner 140 is configured to scan the information code on the certificate.

The information code scanner 140 scans the information code on the certificate, thereby providing a hardware basis for the control system of the temporary manufacturing equipment to judge whether the two certificates are matched or not, and binding the information of the certificate with the user information. Specifically, the number of information code scanners 140 may be configured as one, two, or other suitable number, and the installation location of the information code scanners 140 may be disposed at the upper evidence base 130, the lower evidence base 410, or other suitable location.

Referring to fig. 1 and 2, in one embodiment, the transferring device 500 includes a first transferring component 510, a second transferring component 520, a third transferring component 530, and an extracting component 540, where the extracting component 540 is used to extract and release a certificate, the first transferring component 510 is connected to the extracting component 540, and the first transferring component 510 is used to drive the extracting component 540 to move along a first axis. The second relay assembly 520 is configured to drive the first relay assembly 510 and the extraction assembly 540 to move along a second axis, and the third relay assembly 530 is configured to drive the first relay assembly 510, the second relay assembly 520, and the third relay assembly 530 to move along a third axis, where the first axis, the second axis, and the third axis are perpendicular to each other.

Through the cooperation of the first transferring component 510, the second transferring component 520 and the third transferring component 530, the extracting component 540 can do linear motion in three dimensions of the three-dimensional space, so that the extracting component 540 can move to the position where the certificate is located to extract the certificate, and the certificate is released after being driven to move to the target position.

Specifically, the extraction assembly 540 may be a suction cup structure. The first transfer assembly 510, the second transfer assembly 520, and the third transfer assembly 530 may use a guide rail and a slider as a guide structure for linear motion, use a motor or an air cylinder as a power source for linear motion, and use a belt transmission structure, a chain transmission structure, or a rack and pinion transmission structure as a transmission structure for linear motion.

Referring to fig. 1 and 2, in one embodiment, the card manufacturing device further includes an electronic control device 700, where the electronic control device 700 is configured to provide a hardware basis for power, signal interaction, and control of the card manufacturing device.

The foregoing description of the utility model has been presented for purposes of illustration and description, and is not intended to be limiting. Several simple deductions, modifications or substitutions may also be made by a person skilled in the art to which the utility model pertains, based on the idea of the utility model.

Claims (10)

1. A temporary card manufacturing apparatus, comprising:

the device comprises a certification device, a certification device and a printing device, wherein the certification device comprises a conveying mechanism and a double-sheet separating mechanism, and the conveying mechanism is used for conveying unprinted certificates; the double-sheet separating mechanism is positioned on the movement path of the certificate and comprises a abutting piece and a friction piece, wherein the abutting piece is used for abutting the friction piece with the certificate; the friction piece is used for preventing certificates which are contacted with the friction piece from passing through the friction piece in the overlapped two certificates when the overlapped two certificates pass through the friction piece;

a printer for printing information on a certificate;

the certificate issuing device is used for outputting a certificate for completing printing;

and the transfer device is used for transferring certificates among the certification device, the printer and the certification device.

2. An evidence-feeding device of a temporary card manufacturing apparatus, comprising:

a transport mechanism for transporting unprinted certificates;

the double-sheet separating mechanism is positioned on the movement path of the certificate and comprises a propping piece and a friction piece, wherein the propping piece is used for propping the friction piece against the certificate; the friction piece is used for preventing certificates which are contacted with the friction piece from passing through the friction piece in the overlapped two certificates when the overlapped two certificates pass through the friction piece.

3. The certification apparatus of claim 2, wherein the friction member comprises a mounting shaft, a mounting frame and a friction plate, the mounting shaft is perpendicular to the movement path of the certification, the mounting frame is rotatably connected with the mounting shaft, and the friction plate covers the side of the mounting frame facing the certification; the mounting frame can rotate around the mounting shaft so as to drive the friction plate to move close to or far away from the certificate.

4. A certification apparatus according to claim 3, wherein the abutting member comprises an elastic member and an abutting seat, one end of the elastic member abuts against the mounting frame, the other end abuts against the abutting seat, and an elastic restoring force of the elastic member is used for driving the mounting frame to rotate in a direction approaching the certificate.

5. The forensic device of claim 2 further comprising a pressing mechanism located in the path of movement of the certificate for compacting and ironing the certificate passing through the pressing mechanism.

6. The forensic device according to claim 5 wherein the pressing mechanism comprises a pressing base, a heating element, a pressing wheel and a pressing drive assembly, the pressing base having a pressing channel, the heating element being disposed within the pressing channel for heating a certificate entering the pressing channel; the pressing driving assembly is used for driving the flattening wheel to rotate and flattening the heated certificate.

7. The forensic device according to claim 2 further comprising a forensic base having a forensic location for storing unprinted certificates and a forensic location on the transfer path of the transfer device; the conveying mechanism is used for conveying the certificate of the certificate storing position to the upper certificate position; the conveying mechanism comprises a certificate feeding driving assembly and a certificate feeding driving wheel, wherein the certificate feeding driving wheel is used for being in contact with the certificate, and the certificate feeding driving assembly is used for driving the certificate feeding driving wheel to rotate so as to drive the certificate to move.

8. The forensic device according to claim 7 wherein the forensic drive assembly comprises a forensic motor, a forensic driving pulley, a forensic driven pulley, a forensic belt and a first forensic spindle; the first upper certificate rotating shaft is rotationally connected with the upper certificate base, and the upper certificate driving wheel is connected with the first upper certificate rotating shaft; the output shaft of the upper evidence motor is connected with the upper evidence driving belt wheel, the upper evidence driven belt wheel is connected with the first upper evidence rotating shaft, and the upper evidence driving belt wheel is connected with the upper evidence driven belt wheel.

9. The forensic device according to claim 7 wherein the transport mechanism further comprises a swing assembly, the swing assembly being disposed above the forensic location; the swing assembly comprises a swing frame, a paper rubbing wheel, a swing frame driving assembly and a paper rubbing transmission assembly; the swing frame is provided with a first side and a second side which are oppositely arranged, the first side of the swing frame is arranged on the certificate feeding base in a swinging way, and the paper rubbing wheel is rotationally connected with the second side of the swing frame; the swing frame driving assembly is used for driving the swing frame to swing so as to drive the paper rubbing wheel to move close to and far away from the certificate storage position; the paper rubbing transmission assembly is in transmission connection with the upper certificate driving assembly, the upper certificate driving assembly can drive the paper rubbing wheel to rotate through the paper rubbing transmission assembly, and the paper rubbing wheel is used for driving the contacted certificate to move to be contacted with the upper certificate driving wheel when rotating.

10. A temporary manufacturing apparatus comprising a certification device as claimed in any one of claims 2 to 9.